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Radical Formation: Abstraction00:47

Radical Formation: Abstraction

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The electron of an atom can be abstracted from a compound by a relatively unstable radical to generate a new radical of relatively greater stability. For example, an initiator which forms radicals by homolysis can abstract a suitable species like a hydrogen atom or a halogen atom from a compound to generate a new radical. This ability of radicals to propagate by abstraction is a crucial feature of radical chain reactions.
Even though homolysis produces radicals, it is different from radical...
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Radical Formation: Elimination00:51

Radical Formation: Elimination

1.6K
Another method of radical formation is the elimination process. It is the opposite of the addition route and is driven by the instability of the radical. For example, as depicted in Figure 1, dibenzoyl peroxide yields a pair of unstable radicals upon homolysis. Given its instability, this radical spontaneously undergoes elimination via a C–C bond cleavage to form a relatively more stable phenyl radical. The mechanism involves cleavage of the bond between the α and β positions...
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Radical Formation: Homolysis00:54

Radical Formation: Homolysis

3.6K
A bond is formed between two atoms by sharing two electrons. When this bond is broken by supplying sufficient energy, either two electrons can be taken up by one atom forming ions by the cleavage called heterolysis, or the two electrons are shared by two atoms, with one each creating radicals by the cleavage called homolysis.
3.6K
Radical Reactivity: Overview01:11

Radical Reactivity: Overview

2.2K
Radicals, the highly reactive species, gain stability by undergoing three different reactions. The first reaction involves a radical-radical coupling, in which a radical combines with another radical, forming a spin‐paired molecule. The second reaction is between a radical and a spin‐paired molecule, generating a new radical and a new spin‐paired molecule. The third reaction is radical decomposition in a unimolecular reaction, forming a new radical and a spin‐paired...
2.2K
Radical Reactivity: Intramolecular vs Intermolecular01:33

Radical Reactivity: Intramolecular vs Intermolecular

1.4K
Radical reactions can occur either intermolecularly or intramolecularly. In an intermolecular radical reaction, a nucleophilic radical adds to an electrophilic alkene or vice versa. In such reactions, the radical and generally the alkene, which is also called the radical trap, are two different molecules. Additionally, for such intermolecular reactions to occur, the radical trap must be active, present in an excess concentration, and the radical starting material must have a weak...
1.4K
Radical Reactivity: Steric Effects01:10

Radical Reactivity: Steric Effects

1.6K
The presence of electron-donating, electron-withdrawing, or conjugating groups adjacent to a radical center, imparts electronic stabilization to the radicals. Examples of such electronically-stabilized radicals are triphenylmethyl, tetramethylpiperidine‐N‐oxide, and 2,2‐diphenyl‐1‐picrylhydrazyl. These radicals are remarkably stable and are known as persistent radicals. Some of the persistent radicals can even be isolated and purified.
Along with electronic...
1.6K

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Updated: May 2, 2026

Monitoring Equilibrium Changes in RNA Structure by 'Peroxidative' and 'Oxidative' Hydroxyl Radical Footprinting
13:41

Monitoring Equilibrium Changes in RNA Structure by 'Peroxidative' and 'Oxidative' Hydroxyl Radical Footprinting

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La función de dominio BLUF no requiere un estado intermedio de estado radical metastable.

Andras Lukacs1, Richard Brust, Allison Haigney

  • 1Department of Chemistry, Stony Brook University , Stony Brook, New York 11794-3400, United States.

Journal of the American Chemical Society
|March 4, 2014
PubMed
Resumen
Este resumen es generado por máquina.

La transferencia de electrones fotoinducida (PET) no es central para la luz azul utilizando la función de la proteína flavina (BLUF). Los estudios muestran que los radicales intermedios no se observan ni se correlacionan con la fotoactividad, lo que sugiere vías alternativas no radicales.

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Área de la Ciencia:

  • La bioquímica es la bioquímica.
  • La fotoquímica es la fotoquímica.
  • Biología Molecular Biología Molecular

Sus antecedentes:

  • La luz azul que utiliza proteínas flavin (BLUF) son sensores de luz azul cruciales en las células.
  • El paso inicial activado por la luz en las proteínas BLUF sigue sin estar claro.
  • La transferencia de electrones fotoinducida (PET) que involucra tirosina y flavina es un mecanismo propuesto.

Objetivo del estudio:

  • Investigar el papel del PET en el fotociclo de tres proteínas BLUF.
  • Determinar si los radicales intermedios formados a través del PET son esenciales para la función de la proteína BLUF.

Principales métodos:

  • Espectroscopia infrarroja transitorio de banda ancha ultrarrápida para monitorear la dinámica fotoquímica.
  • Mutagénesis dirigida al sitio y etiquetado de isótopos para identificar los radicales intermedios.
  • Mutagénesis de aminoácidos no naturales para alterar la fuerza impulsora de la transferencia de electrones.

Principales resultados:

  • Los radicales intermedios indicativos de PET no se observaron de manera consistente en dos de las tres proteínas BLUF estudiadas.
  • El análisis mutacional y el etiquetado isotópico confirmaron la presencia de flavinas y estados radicales de proteínas.
  • La alteración de la fuerza motriz para el PET a través de la sustitución de fluorotirosina no produjo resultados consistentes con un mecanismo de PET.

Conclusiones:

  • Los intermediarios de PET observados en las proteínas BLUF no están correlacionados con la fotoactividad.
  • Es poco probable que los radicales intermedios sean centrales en el mecanismo operativo de las proteínas BLUF.
  • Las vías no radicales, como la tautomerización de ceto-enol, son alternativas plausibles para la fotoactivación de la proteína BLUF.